Radio station system, radio terminal, and methods therein

ABSTRACT

A radio station ( 2 ) transmits configuration information ( 501 ) to a radio terminal ( 1 ). The configuration information ( 501 ) indicates, on a cell-by-cell basis, at least one specific cell on which the radio terminal ( 1 ) is allowed to perform at least one of data transmission and data reception on a radio bearer used for uplink transmission or downlink transmission or both via a common Packet Data Convergence Protocol (PDCP) layer ( 402 ). As a result, in a radio architecture that provides tight interworking of two different Radio Access Technologies (RATs), it is for example possible to allow an eNB to indicate, to a radio terminal (UE), a specific cell on which the UE should perform uplink transmission.

CROSS REFERENCE TO RELATED APPLICATIONS

This is a continuation application of U.S. application Ser. No.15/781,174, filed Jun. 4, 2018, which is a National Stage ofInternational Application No. PCT/JP2016/087329 filed Dec. 15, 2016,claiming priority based on Japanese Patent Application No. 2016-002878filed Jan. 8, 2016, the disclosures of which are incorporated byreference herein in their entireties.

TECHNICAL FIELD

The present disclosure relates to communication between a radio stationand a radio terminal using a plurality of Radio Access Technologies(RATs).

BACKGROUND ART

The 3rd Generation Partnership Project (3GPP) is starting to work on thestandardization for 5G, i.e., 3GPP Release 14, in 2016 to make 5G acommercial reality in 2020. 5G is expected to be realized by continuousenhancement/evolution of LTE and LTE-Advanced and an innovativedevelopment by an introduction of a new 5G air-interface (i.e., a newRadio Access Technology (RAT)). The new RAT (i.e., New 5G RAT) supports,for example, frequency bands higher than the frequency bands (e.g., 6GHz or lower) supported by the LTE/LTE-Advanced and itsenhancement/evolution. For example, the new RAT supports centimeter-wavebands (10 GHz or higher) and millimeter-wave bands (30 GHz or higher).

Higher frequency can provide higher-rate communication. However, becauseof its frequency properties, coverage of the higher frequency is morelocal. Therefore, high frequencies are used to boost capacity and datarates in specific areas, while wide-area coverage is provided by lowercurrent frequencies. That is, in order to ensure the stability of New 5GRAT communication in high frequency bands, tight integration orinterworking between low and high frequencies (i.e., tight integrationor interworking between LTE/LTE-Advanced and New 5G RAT) is required. A5G supporting radio terminal (i.e., 5G User Equipment (UE)) is connectedto both of a low frequency band cell and a high frequency band cell(i.e., a LTE/LTE-Advanced cell and a new 5G cell) by using CarrierAggregation (CA) or Dual Connectivity (DC), or a modified techniquethereof.

Non-Patent Literature 1 discloses user-plane and control-planearchitectures to use both the LTE air interface (i.e., LTE RAT) and thenew 5G air interface (i.e., New 5G RAT). In some implementations, acommon Radio Resource Control (RRC) layer and a common Packet DataConvergence Protocol (PDCP) layer (or sublayer) are used. The commonPDCP layer is connected to LTE lower layers and New 5G lower layers, andprovides an upper layer with a transfer service of user plane data andcontrol plane data through the LTE lower layers and the New 5G lowerlayers. The LTE lower layers include a Radio Link Control (RLC) layer, aMedium Access Control (MAC) layer, and a physical layer for the LTE-RAT.In a similar way, the New 5G lower layers include an RLC layer, a MAClayer, and a physical layer for the New 5G RAT.

The term “LTE” used in this specification includes enhancements of LTEand LTE-Advanced for 5G to provide tight interworking with the New 5GRAT, unless otherwise indicated. Such enhancements of LTE andLTE-Advanced are also referred to as LTE-Advanced Pro, LTE+, or enhancedLTE (eLTE). Further, the term “5G” or “New 5G” in this specification isused, for the sake of convenience, to indicate an air-interface (RAT)that is newly introduced for the fifth generation (5G) mobilecommunication systems, and nodes, cells, protocol layers, etc. relatedto this air-interface. The names of the newly introduced air interface(RAT), and nodes, cells, and protocol layers related thereto will bedetermined in the future as the standardization work progresses. Forexample, the LTE RAT may be referred to as Primary RAT (P-RAT or pRAT)or Master RAT. Meanwhile, the New 5G RAT may be referred to as SecondaryRAT (S-RAT or sRAT).

CITATION LIST Non Patent Literature

-   [Non-Patent Literature 1] Da Silva, I.; Mildh, G.; Rune, J.;    Wallentin, P.; Vikberg, J.; Schliwa-Bertling, P.; Rui Fan, “Tight    Integration of New 5G Air Interface and LTE to Fulfill 5G    Requirements,” in Vehicular Technology Conference (VTC Spring), 2015    IEEE 81st, pp. 1-5, 11-14 May 2015

SUMMARY OF INVENTION Technical Problem

The inventors have studied the 5G radio architecture that provides tightinterworking of the LTE RAT and the New 5G RAT and found some problems.For example, there is a problem in the architecture using the commonPDCP layer disclosed in Non-Patent Literature 1 that it is difficult forthe eNB to indicate, to the UE, a specific cell on which the UE shouldperform uplink (UL) transmission.

In the existing Dual Connectivity, a Master eNB (MeNB) configures a UEwith a link on which UL PDCP Protocol Data Units (PDUs) is to betransmitted. However, the MeNB in DC can only configure the UE with acell group on which UL PDCP PDUs is to be transmitted. That is, the MeNBin DC can only indicate, to the UE, which one of the Master Cell Group(MCG) and the Secondary Cell Group (SCG) the UE should transmit UL PDCPPDUs on. The MCG is composed of one or more cells provided by the MeNB.The SCG is composed of one or more cells provided by the Secondary(SeNB). In other words, the MeNB in DC cannot indicate, to the UE, whichspecific cell in the MCG or the SCG the UE should transmit UL PDCP PDUson.

Accordingly, one of the objects to be attained by embodiments disclosedherein is to provide an apparatus, a method, and a program that allow aneNB to indicate, to a radio terminal (UE), a specific cell on which theUE should perform uplink transmission in a radio architecture thatprovides tight interworking of two different RATs. It should be notedthat this object is merely one of the objects to be attained by theembodiments disclosed herein. Other objects or problems and novelfeatures will be made apparent from the following description and theaccompanying drawings.

Solution to Problem

In a first aspect, a radio station system includes one or more radiostations. The one or more radio stations are configured to provide afirst radio protocol stack to communicate with a radio terminal on oneor more first cells in accordance with a first radio access technology,a second radio protocol stack to communicate with the radio terminal onone or more second cells in accordance with a second radio accesstechnology, and a common Packet Data Convergence Protocol (PDCP) layerassociated with both the first and second radio protocol stacks. The oneor more radio stations are configured to select from the one or morefirst cells and the one or more second cells, on a cell-by-cell basis,at least one specific cell on which the radio terminal is allowed toperform at least one of data transmission and data reception on a radiobearer used for uplink transmission or downlink transmission or both viathe common PDCP layer. Furthermore, the at least one processor isconfigured to transmit configuration information indicating the at leastone specific cell to the radio terminal.

In a second aspect, a method in a radio station system, including one ormore radio stations, includes:

(a) providing a first radio protocol stack to communicate with a radioterminal on one or more first cells in accordance with a first radioaccess technology, a second radio protocol stack to communicate with theradio terminal on one or more second cells in accordance with a secondradio access technology, and a common Packet Data Convergence Protocol(PDCP) layer associated with both the first and second radio protocolstacks;(b) selecting from the one or more first cells and the one or moresecond cells, on a cell-by-cell basis, at least one specific cell onwhich the radio terminal is allowed to perform at least one of datatransmission and data reception on a radio bearer used for uplinktransmission or downlink transmission or both via the common PDCP layer;and(c) transmitting configuration information indicating the at least onespecific cell to the radio terminal.

In a third aspect, a radio terminal includes a memory and at least oneprocessor coupled to the memory. The at least one processor isconfigured to provide a first radio protocol stack to communicate with aradio station on one or more first cells in accordance with a firstradio access technology, a second radio protocol stack to communicatewith the radio station on one or more second cells in accordance with asecond radio access technology, and a common Packet Data ConvergenceProtocol (PDCP) layer associated with both the first and second radioprotocol stacks. Further, the at least one processor is configured toreceive, from the radio station, configuration information indicating,on a cell-by-cell basis, at least one specific cell on which the radioterminal is allowed to perform at least one of data transmission anddata reception on a radio bearer used for uplink transmission ordownlink transmission or both via the common PDCP layer. Furthermore,the at least one processor is configured to perform at least one of thedata transmission and the data reception on the radio bearer via the atleast one specific cell in accordance with the configurationinformation.

In a fourth aspect, a method in a radio terminal includes:

(a) providing a first radio protocol stack to communicate with a radiostation on one or more first cells in accordance with a first radioaccess technology, a second radio protocol stack to communicate with theradio station on one or more second cells in accordance with a secondradio access technology, and a common Packet Data Convergence Protocol(PDCP) layer associated with both the first and second radio protocolstacks;(b) receiving, from the radio station, configuration information thatindicates, on a cell-by-cell basis, at least one specific cell on whichthe radio terminal is allowed to perform at least one of datatransmission and data reception on a radio bearer used for uplinktransmission or downlink transmission or both via the common PDCP layer;and(c) performing at least one of the data transmission and the datareception on the radio bearer via the at least one specific cell inaccordance with the configuration information.

In a fifth aspect, a program includes instructions (software codes)that, when loaded into a computer, cause the computer to perform themethod according to the above-described second or fourth aspect.

Advantageous Effects of Invention

According to the above-described aspects, it is possible to provide anapparatus, a method, and a program that allow an eNB to indicate, toradio terminal (UE), a specific cell on which the UE should performuplink transmission in a radio architecture that provides tightinterworking of two different RATs.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a diagram showing a configuration example of a radiocommunication network according to several embodiments;

FIG. 2 is a diagram showing a configuration example of the radiocommunication network according to the several embodiments;

FIG. 3 is a diagram showing another configuration example of the radiocommunication network according to the several embodiments;

FIG. 4 is a diagram showing an example of a radio protocol stackaccording to the several embodiments;

FIG. 5 is a diagram showing an example of the radio protocol stackaccording to the several embodiments;

FIG. 6 is a diagram showing an example of a layer-2 structure for uplinkaccording to the several embodiments;

FIG. 7 is a sequence diagram showing one example of operations of aradio terminal and a base station according to a first embodiment;

FIG. 8 is a sequence diagram showing one example of operations of theradio terminal and the base station according to the first embodiment;

FIG. 9 is a diagram showing one example of information elements used bya base station to indicate to a radio terminal a specific cell used foruplink transmission;

FIG. 10 is a diagram showing one example of information elements used bya base station to indicate to a radio terminal a specific cell used foruplink transmission;

FIG. 11 is a table showing an example of a key used for generation of atemporary key for ciphering/deciphering of each radio bearer accordingto a second embodiment;

FIG. 12 is a table showing an example of a key used for generation of atemporary key for ciphering/deciphering of each radio bearer accordingto the second embodiment;

FIG. 13 is a flowchart showing one example of operations of a radioterminal according to a third embodiment;

FIG. 14 is a block diagram showing a configuration example of a radioterminal according to the several embodiments; and

FIG. 15 is a block diagram showing a configuration example of a basestation according to the several embodiments.

DESCRIPTION OF EMBODIMENTS

Specific embodiments are described hereinafter in detail with referenceto the drawings. The same or corresponding elements are denoted by thesame reference symbols throughout the drawings, and repetitivedescriptions are avoided for clarity.

Each of embodiments described below may be used individually, or two ormore of the embodiments may be appropriately combined with one another.These embodiments include novel features different from one another.Accordingly, these embodiments contribute to achieving objects orsolving problems different from one another and contribute to obtainingadvantages different from one another.

The following descriptions on the embodiments mainly focus on specificexamples with regard to the 5G radio architecture that provides tightinterworking of the LTE RAT and the New 5G RAT. However, theseembodiments are not limited to being applied to the 5G radioarchitecture and may also be applied to other radio architectures thatprovide tight interworking of two different RATs.

First Embodiment

FIG. 1 shows a configuration example of a radio communication networkaccording to several embodiments including this embodiment. In theexample shown in FIG. 1, the radio communication network includes aradio terminal (UE) 1 and an integrated base station (i.e., integratedeNB) 2. The UE 1 is a 5G UE and connects to both one or more LTE cells(e.g., cells 21 and 22) and one or more New 5G cells (e.g., cells 23 and24) using CA, DC, or an enhancement thereof. In the followingdescription, one or more LTE cells are referred to as an LTE cell group(CG) and one or more New 5G cells used by the 5G UE 1 are referred to asa New 5G CG. Each of the cells in the LTE CG and New 5G CG has beenconfigured for the 5G UE 1 by the integrated eNB 2 and has beenactivated by the integrated eNB 2. In some implementations, frequencybands (e.g., F1 and F2) of the LTE CG (e.g., the cells 21 and 22) arelower frequency bands (e.g., lower than 6 GHz) and frequency bands(e.g., F3 and F4) of the New 5G CG (e.g., the cells 23 and 24) arehigher frequency bands (e.g., higher than 6 GHz).

The integrated eNB 2 supports 5G and provides a plurality of cells thatuse a plurality of component carriers (CCs) having different frequenciesand using different RATs. In the example shown in FIG. 1, the integratedeNB 2 provides LTE cells 21 and 22 and New 5G cells 23 and 24. Theintegrated eNB 2 communicates with the 5G UE 1 via both the LTE CG(e.g., the cells 21 and 22) and the New 5G CG (e.g., the cells 23 and24) using CA, DC, or an enhancement thereof. Further, the integrated eNB2 is connected to a core network, that is, an integrated Evolved PacketCore (i.e., integrated EPC) 41. The integrated EPC 41 provides LTE corenetwork functions and 5G new core network functions. In someimplementations, the integrated eNB 2 may be connected to a 5G specificcore network (i.e., 5G specific EPC 42).

As shown in FIG. 2, a remote radio unit 3 may be used to provide atleast one of the cells of the integrated eNB 2 (e.g., New 5G cells 23and 24). In the configuration shown in FIG. 2, the integrated eNB 2performs digital signal processing regarding uplink and downlinksignals, and meanwhile the radio unit 3 performs analog signalprocessing of the physical layer. For example, the integrated eNB 2 andthe radio unit 3 are connected to each other by an optical fiber, and adigital baseband signal is transferred through this optical fiber inaccordance with the Common Public Radio Interface (CPRI) standard. Theconfiguration shown in FIG. 2 is referred to as a Cloud Radio AccessNetwork (C-RAN). The radio unit 3 is referred to as a Remote Radio Head(RRH) or a Remote Radio Equipment (RRE). The integrated eNB 2 thatperforms baseband digital signal processing is referred to as a BasebandUnit (BBU). Further, information about any one of the layers 1, 2, and 3(or a signal containing this information) may be transferred using afronthaul (interface) that is to be standardized by, for example, 3GPPor Small Cell Forum. For example, a form in which the fronthaul connectsbetween the L1 and the L2 or between Sub-layers in the L2 is alsoreferred to as L2 C-RAN. In this case, the integrated eNB 2 and the RRH3 shown in FIG. 2 are also referred to as a Digital Unit (DU) and aRadio Unit (RU), respectively.

In the configuration examples shown in FIGS. 1 and 2, the LTE radioprotocol and the New 5G radio protocol are implemented in one node(i.e., the integrated eNB 2). Accordingly, the configuration examplesshown in FIGS. 1 and 2 are referred to as co-located deployments orco-located RAN. In the case of the L2 C-RAN configuration, a part of theNew 5G radio protocol may be deployed in the RU. However, in anotherconfiguration example, non co-located deployments or non co-located RANmay be employed. In the Non co-located deployments, the LTE radioprotocol and the New 5G radio protocol are provided by two nodes (eNBs)different from each other. These two nodes are installed, for example,at two different sites geographically spaced apart from each other.

FIG. 3 shows an example of the non co-located deployments of the radiocommunication network according to several embodiments including thisembodiment. In the example shown in FIG. 3, the radio communicationnetwork includes a 5G UE 1, an LTE+eNB 5, and a 5G specific eNB 6. TheLTE+eNB 5 provides an LTE CG (e.g., the cells 21 and 22) and the 5Gspecific eNB 6 provides a New 5G CG (e.g., the cells 23 and 24). TheLTE+eNB 5 is connected to the 5G specific eNB 6 by a communication line,such as an optical fiber link or a point-to-point radio link, andcommunicates with the 5G specific eNB 6 on an inter-base-stationinterface 301 (e.g., enhanced X2 interface). The LTE+eNB 5 and the 5Gspecific eNB 6 interwork with each other to enable the 5G UE 1 toconnect to both the LTE CG and the 5G CG using CA, DC, or an enhancementthereof.

FIG. 4 shows one example of the radio protocol stack supported by the 5GUE 1 and the integrated eNB 2. A radio protocol stack 400 shown in FIG.4 includes a unified (or integrated) RRC layer 401 and a unified (orintegrated) PDCP layer (or sublayer) 402. The integrated RRC layer 401and the integrated PDCP layer 402 may also be referred to as a commonRRC layer and a common PDCP layer, respectively. The radio protocolstack 400 further includes LTE lower layers and New 5G lower layers. TheLTE lower layers include an LTE RLC layer 403, an LTE MAC layer 404, andan LTE PHY layer 405. The New 5G lower layers include a New RLC layer406, a New MAC layer 407, and a New PHY layer 408. In the case of usingthe integrated eNB 2, some of the functions of the LTE PHY layer 405(e.g., analog signal processing) may be provided by an RRH for LTE. In asimilar way, some of the functions of the New PHY layer 408 (e.g.,analog signal processing) may be provided by an RRH for New 5G. Further,in the case of using the above-described L2 C-RAN configuration, some ofthe functions of the New PHY layer, the New MAC layer, or the New RLClayer (and the functions of layers lower than it) may be provided by anRU for New 5G.

The integrated RRC layer 401 provides control-plane functions in the LTERAT and the New 5G RAT. The main services and functions provided by theintegrated RRC layer 401 include the following:

Transmission of system information for non-access stratum (NAS) andaccess stratum (AS);

Paging;

Establishment, maintenance, and release of RRC connections;

Security functions including key management;

Configuration, maintenance, and release of radio bearers;

Configuration of lower layer protocols (i.e., PDCP, RLC, MAC, and PHY);

QoS management;

UE measurement report and configuration thereof; and

Transfer of NAS messages between a UE and a core network.

The integrated RRC layer 401 communicates with the integrated PDCP layer402 to perform management of radio bearers, control ofciphering/deciphering of data of the user plane (i.e., data radiobearers), control of ciphering/deciphering of data (i.e., RRC PDUs) ofthe control plane (i.e., signalling radio bearers), and control ofintegrity protection of data (i.e., RRC PDUs) of the control plane(i.e., signalling radio bearers). Further, the integrated RRC layer 401controls the LTE RLC layer 403, the LTE MAC layer 404, and the LTE PHYlayer 405, and also controls the New RLC layer 406, the New MAC layer407, and the New PHY layer 408.

The integrated PDCP layer 402 provides an upper layer with transferservices of data of data radio bearers and signalling radio bearers. Theintegrated PDCP layer 402 receives services from the LTE RLC layer 403and the New RLC layer 406. That is, the integrated PDCP layer 402 isprovided with a transfer service of PDCP PDUs through the LTE RAT by theLTE RLC layer 403 and is provided with a transfer service of PDCP PDUsthrough the New 5G RAT by the New RLC layer 406.

It should be noted that the radio protocol stack 400, which uses theintegrated PDCP layer 402, shown in FIG. 4 can be applied not only tothe co-located deployments (e.g., FIGS. 1 and 2) but also to the nonco-located deployments (e.g., FIG. 3). That is, as shown in FIG. 5, inthe non co-located deployments, the LTE+eNB 5 is arranged in a site 501and provides the integrated RRC layer 401, the integrated PDCP layer402, the LTE RLC layer 403, the LTE MAC layer 404, and the LTE PHY layer405. In contrast, the 5G specific eNB 6 is arranged in another site 502and provides the New RLC layer 406, the New MAC layer 407, and the NewPHY layer 408.

In some implementations, the 5G specific eNB 6 used in the nonco-located deployments may include a New RRC layer 511 and a New PDCPlayer 512. Further, the 5G specific eNB 6 may include a controlinterface or connection (e.g., an S1-MME interface or an S1-U interface)with a core network (e.g., the integrated EPC 41 or the 5G specific EPC42) for the 5G UE 1. In some implementations, the New RRC layer 511 mayconfigure the lower layers 406-408 of the New 5G CG (e.g., New 5G cells23 and 24) and transmit system information (i.e., Master InformationBlock (MIB), or System Information Blocks (SIBs), or both) via the New5G CG. The New RRC layer 511 may configure a signalling radio bearerwith the 5G UE 1, also configure the lower layers 406-408 of the New 5GCG (e.g., the New 5G cells 23 and 24) and the New PDCP layer 512, andthen transmit or receive RRC messages to or from the 5G UE 1 through theNew 5G CG. The New RRC layer 511 may transfer NAS messages between thecore network (e.g., the integrated EPC 41 or the 5G specific EPC 42) andthe 5G UE 1. The New PDCP layer 512 provides the New RRC layer 511 witha transfer service of RRC messages via the New 5G lower layers 406-408.

The New RRC layer 511 may depend on the integrated RRC layer 401 (i.e.,have a dependency relationship) or may perform control similar to thatperformed by the integrated RRC layer 401 (i.e., have a similarfunction). In the former case (i.e., dependency relationship), the 5Gspecific eNB 6 (or the New RRC layer 511 thereof) may generate RRCconfiguration information with respect to a New 5G cell(s) (i.e., New 5GCG) in response to an instruction or a request from the LTE+eNB 5 (orthe integrated RRC layer 401 thereof). The 5G specific eNB 6 (or the NewRRC layer 511 thereof) may transmit this RRC configuration informationto the LTE+eNB 5 (or the integrated RRC layer 401 thereof) and theLTE+eNB 5 may transmit an RRC message containing this RRC configurationinformation (e.g., an RRC Connection Reconfiguration message) to the 5GUE 1 on an LTE cell (i.e., LTE CG). Alternatively, the 5G specific eNB 6(or the New RRC layer 511 thereof) may transmit an RRC messagecontaining this RRC configuration information to the 5G UE 1 on a New 5Gcell.

The 5G UE 1 may support the protocol stack shown in FIG. 4 or supportanother protocol stack to communicate with the radio network shown inFIG. 5. For example, the 5G UE 1 may have an RRC layer (i.e., a masterRRC layer or a primary RRC layer) corresponding to the integrated RRClayer 401 of the LTE+eNB 5 and an auxiliary RRC layer (i.e., a sub RRClayer or a secondary RRC layer) corresponding to the New RRC layer 511of the 5G specific eNB 6. For example, the sub RRC layer may perform oneor both of transmission and reception (or one or both of generation andrestoration) of a part of the RRC configuration information controlledby the master RRC layer. The 5G UE 1 may receive both the RRCconfiguration information regarding a LTE cell(s) (i.e., LTE CG) and theRRC configuration information regarding a New 5G cell(s) (i.e., New 5GCG) through an LTE cell or through a New 5G cell. Alternatively, the 5GUE 1 may receive the RRC configuration information regarding a LTEcell(s) (i.e., LTE CG) through an LTE cell and meanwhile receive the RRCconfiguration information regarding a New 5G cell(s) (i.e., New 5G CG)through a New 5G cell.

The radio protocol stack shown in FIG. 4 is merely one example and,alternatively, the 5G UE 1 and the integrated eNB 2 may support anotherprotocol stack. For example, in FIG. 4, the integrated PDCP layer 402integrates (or allows interworking of) the LTE lower layers and the New5G lower layers. Alternatively, an integrated MAC layer may be used tointegrate (or allow interworking of) the LTE PHY layer 405 and the NewPHY layer 408.

FIG. 6 shows one example of the layer-2 structure for uplink accordingto the several embodiments. An integrated PDCP layer 602, an LTE RLClayer 603, an LTE MAC layer 604, a New RLC layer 606, and a New MAClayer 607 shown in FIG. 6 respectively correspond to the integrated PDCPlayer 402, the LTE RLC layer 403, the LTE MAC layer 404, the New RLClayer 406, and the New MAC layer 407 shown in FIGS. 4 and 5.

The integrated PDCP layer 602 includes one or more PDCP entities. EachPDCP entity transports data of one radio bearer. Each PDCP entity isassociated with either the user plane or the control plane depending onwhich radio bearer (i.e., a data radio bearer (DRB) or a signallingradio bearer (SRB)) it transports data from. In the example shown inFIG. 6, the integrated PDCP layer 602 includes three PDCP entities 6021,6022, and 6023 that correspond to three data radio bearers DRB #1, DRB#2, and DRB #3, respectively.

The data of the DRB #1 is transmitted from the 5G UE 1 to the integratedeNB 2 (or the LTE+eNB 5) via the LTE RAT on the LTE CG (e.g., the LTEcells 21 and 22). Accordingly, the DRB #1 may be hereinafter referred toas an LTE bearer. The DRB #1 is similar to an MCG bearer in LTE Release12 DC.

The data of the DRB #2 is transmitted from the 5G UE 1 to the integratedeNB 2 (or the 5G specific eNB 6) via the New 5G RAT on the New 5G CG(e.g., the New 5G cells 23 and 24). Accordingly, the DRB #2 may behereinafter referred to as a New 5G bearer. When the data is transmittedon the New 5G CG managed by the 5G specific eNB 6, the DRB #2 is similarto an SCG bearer in LTE Release 12 DC. Alternatively, when the data istransmitted on the New 5G CG managed by the integrated eNB 2, the DRB #2may be similar to a bearer on the SCG side of a split bearer in LTERelease 12 DC.

The DRB #3 is similar to a split bearer in LTE Release 12 DC. That is,the DRB #3 is associated with both of one logical channel of the LTE RATand one logical channel of the New 5G RAT to use both the resources ofthe LTE CG and the resources of the New 5G CG. In the case of the userdata, the logical channel of the LTE RAT is a Dedicated Traffic Channel(DTCH). The logical channel of the New 5G RAT is a 5G logical channelfor the user data that corresponds to the DTCH. The DRB #3 may behereinafter referred to as a split bearer or a unified bearer (anintegrated bearer).

In the case of uplink transmission by the 5G UE 1, the PDCP entity 6021generates PDCP PDUs from data of the DRB #1 (i.e., LTE bearer) and sendsthese PDCP PDUs to an LTE RLC entity 6031. In the case of uplinkreception by the integrated eNB 2 (or the LTE+eNB 5), the PDCP entity6021 receives RLC SDUs (i.e., PDCP PDUs) from the LTE RLC entity 6031and sends data of the DRB #1 to the upper layer.

In the case of uplink transmission by the 5G UE 1, the PDCP entity 6022generates PDCP PDUs from data of the DRB #2 (i.e., New 5G bearer) andsends these PDCP PDUs to a New RLC entity 6061. In the case of uplinkreception by the integrated eNB 2 (or the 5G specific eNB 6), the PDCPentity 6022 receives RLC SDUs (i.e., PDCP PDUs) from the New RLC entity6061 and sends data of the DRB #2 to the upper layer.

In the case of uplink transmission by the 5G UE 1, the PDCP entity 6023generates PDCP PDUs from data of the DRB #3 (i.e., integrated bearer)and routes these PDCP PDUs to an LTE RLC entity 6032 or a New RLC entity6062. In the case of uplink reception by the integrated eNB 2 (or theLTE+eNB 5 and the 5G specific eNB 6), the PDCP entity 6023 reorders PDCPPDUs (i.e., RLC SDUs) received from the LTE RLC entity 6032 and from theNew RLC entity 6062, and then sends data of the DRB #3 to the upperlayer.

Each RLC entity in the LTE RLC layer 603 and the New RLC layer 606 isconfigured, by the integrated RRC entity (i.e., the RRC entity 401 shownin FIG. 4), with RLC Acknowledged Mode (RLC AM) data transfer or RLCUnacknowledged Mode (RLC UM) data transfer, and then provides a transferservice of PDCP PDUs. In the case of uplink transmission by the 5G UE 1,each RLC entity in the LTE RLC layer 603 generates RLC PDUs (i.e., dataof one logical channel) from PDCP PDUs (i.e., RLC SDUs) and sends theseRLC PDUs to a MAC entity 6041 in the LTE MAC layer 604. In a similarway, each RLC entity in the New RLC layer 606 generates RLC PDUs (i.e.,data of one logical channel) from PDCP PDUs (i.e., RLC SDUs) and sendsthem to a MAC entity 6071 in the New MAC layer 607.

In the example shown in FIG. 6, one MAC entity 6041 is used for two LTEcells (i.e., LTE CG) configured for one 5G UE 1. In the case of uplinktransmission by the 5G UE 1, the MAC entity 6041 multiplexes RLC PDUs(i.e., MAC SDUs), which belong to the two logical channels from the twoRLC entities 6031 and 6032, into two transport blocks per TransmissionTime Interval (TTI). The two transport blocks per TTI are sent to theLTE physical layer 405 through two UL transport channels (i.e., UL-SCHs)corresponding to the two LTE cells 21 and 22.

In a similar way, one MAC entity 6071 is used for two New 5G cells(i.e., New 5G CG) configured for one 5G UE 1. In the case of uplinktransmission by the 5G UE 1, the MAC entity 6071 multiplexes RLC PDUs(i.e., MAC SDUs), which belong to two logical channels from two RLCentities 6071 and 6072, into two transport blocks per Transmission TimeInterval (TTI). The two transport blocks per TTI are sent to thephysical layer 408 for New 5G through two UL transport channels (i.e.,UL TrCHs) corresponding to the two New 5G cells 23 and 24.

Further, in this embodiment, the integrated eNB 2 is configured toindicate, to the 5G UE 1, a specific cell on which the 5G UE 1 isallowed to perform at least one of data transmission and data receptionon a radio bearer used for uplink transmission or downlink transmissionor both via the common PDCP layer. For example, the integrated eNB 2 maybe configured to indicate, to the 5G UE 1, a specific cell on which the5G UE 1 should perform uplink (UL) transmission.

In some implementations, the integrated eNB 2 selects, on a cell-by-cellbasis, from one or more LTE cells (e.g., the LTE cells 21 and 22) andone or more New 5G cells (e.g., the New 5G cells 23 and 24) that havebeen configured for the 5G UE 1 (and have been activated), at least onespecific cell on which the 5G UE 1 is allowed to transmit data of an ULradio bearer, which is a radio bearer at least used for uplinktransmission. Then the integrated eNB 2 transmits configurationinformation indicating the selected specific cell to the 5G UE 1. Inother words, the configuration information indicates at least onespecific cell on which the 5G UE 1 is allowed to transmit UL PDCP PDUs(which is generated from data of the UL radio bearer by the integratedPDCP layer 402 or 602). The operation to configure (e.g.,Addition/Modification) the 5G UE 1 with the specific cell on which dataof the UL radio bearer (UL PDCP SDUs or PDUs) is to be transmitted isherein referred to as “Cell-specific bearer mapping”. When the nonco-located deployments are used, the LTE+eNB 5 or the 5G specific eNB 6performs operations for “Cell-specific bearer mapping” in place of theintegrated eNB 2.

In some implementations, the configuration information, which notifiesthe 5G UE 1 of the specific cell for the UL transmission, may beincluded in an RRC message. FIG. 7 shows one example (Process 700) of anoperation of transmitting the configuration information. In Step 701,the integrated eNB 2 transmits to the 5G UE 1 an RRC ConnectionReconfiguration message containing the configuration information for thecell-specific bearer mapping. FIG. 7 is merely one example. For example,the configuration information may be included in another RRC message(e.g., an RRC Connection Setup message). When the non co-locateddeployments are used, the LTE+eNB 5 that provides the integrated RRClayer 401 may perform the transmission in Step 701.

In other implementations, the 5G specific eNB 6 may send to the LTE+eNB5, using an inter-node message (e.g., SCG-Config), configurationinformation for the cell-specific bearer mapping about the New 5G cell,and the LTE+eNB 5 then may transmit this configuration information tothe 5G UE 1. Alternatively, the 5G specific eNB 6 may transmit, to the5G UE 1, an RRC Connection Reconfiguration message containing theconfiguration information for the cell-specific bearer mapping about theNew 5G cell. In these cases, the 5G specific eNB 6 may have an RRC layerto manage the New 5G cell (that is, to perform RRC configuration).

FIG. 8 shows one example of an operation of transmitting theconfiguration information for the cell-specific bearer mapping about theNew 5G cell. The example shown in FIG. 8 reuses an X2AP message and anRRC IE used for information exchange between eNBs in Dual Connectivity(DC). In Option 1 shown in FIG. 8, in Step 801, the LTE+eNB 5 sends tothe 5G specific eNB 6, using an SENB ADDITION REQUEST message, DCconfiguration information (e.g., SCG-ConfigInfo) required for DC. InStep 802, the 5G specific eNB 5 sends to the LTE+eNB 5 an SENB ADDITIONREQUEST ACKNOWLEDGE message containing the configuration information forthe cell-specific bearer mapping about the 5G cell (e.g., Cell-specificbearer mapping for 5G cell). In Step 803, the LTE+eNB 5 transmits an RRCConnection Reconfiguration message containing this configurationinformation to the 5G UE 1.

In contrast, in Option 2 shown in FIG. 8, in Step 811, the LTE+eNB 5sends to the 5G specific eNB 6, using an SENB MODIFICATION REQUESTmessage, DC configuration information (e.g., SCG-ConfigInfo) requiredfor DC. In Step 812, the 5G specific eNB 6 sends an SENB MODIFICATIONREQUEST ACKNOWLEDGE message to the LTE+eNB 5. In Step 813, the 5Gspecific eNB 6 transmits to the 5G UE 1 an RRC ConnectionReconfiguration message containing the configuration information for thecell-specific bearer mapping about the 5G cell (e.g., Cell-specificbearer mapping for the 5G cell). Note that, in Step 812, the 5G specificeNB 6 may send the configuration information for the cell-specificbearer mapping about the 5G cell (e.g., Cell-specific bearer mapping for5G cell) to the LTE+eNB 4. Although the Options 1 and 2 shown in theexample of FIG. 8 uses the SENB ADDITION REQUEST procedure and the SENBMODIFICATION procedure, respectively, each of the Options 1 and 2 mayuse any one of these two procedures and may use another procedure (e.g.,SeNB Change or Inter-MeNB handover) and another message (e.g., SENBMODIFICATION REQUIRED). For example, when the SeNB Change isalternatively used, the 5G UE 1 may perform a Random Access Procedurewith a Target 5G specific eNB (not shown) on the specific cell indicatedby the configuration information for the cell-specific bearer mappingabout the 5G cell (e.g., Cell-specific bearer mapping for 5G cell).

In one example, the configuration information may include a bearerconfiguration regarding an UL radio bearer(s). In this case, the bearerconfiguration includes an indication of the specific cell on which the5G UE 1 is allowed to transmit data of the UL radio bearer(s). Thebearer configuration may indicate that only uplink, only downlink, orboth uplink and downlink is/are targeted.

The following description provides a specific example of the method ofconfiguring the 5G UE 1 with a relationship (or mapping) between a ULradio bearer and a cell(s) on which data of the UL radio bearer is to betransmitted. FIG. 9 shows one example of information elements (IEs) usedby the integrated eNB 2, the LTE+eNB 5, or the 5G specific eNB 6 toindicate to the 5G UE 1 the specific cell to be used for ULtransmission. Specifically, FIG. 9 shows a modification of thedrb-toAddModList IE contained in the RRC Connection Reconfigurationmessage. The drb-toAddModList IE includes a list of the data radiobearers to be added (or modified) to the 5G UE 1. The“applicable-ServCellList” (901) shown in FIG. 9 indicates a list ofserving cells on which the 5G UE is allowed to transmit DRB data, withregard to each DRB to be added or modified. The“applicable-ServCellList” (901) includes one or more serving cellidentifiers (ServCellIndex (903)), as shown in the“applicable-ServCellList” IE (902). Further, the“applicable-ServCellList” IE (902) may include an information element(e.g., drb-direction (904)) indicating the target bearer direction(i.e., only uplink, only downlink, or both uplink and downlink).

In another example, the configuration information may include cellconfiguration regarding at least one serving cell. In this case, thecell configuration indicates whether the 5G UE 1 is allowed to transmitdata of each UL radio bearer in each serving cell. This cellconfiguration may indicate that only uplink, only downlink, or bothuplink and downlink is/are targeted. Further, a cell(s) on which the 5GUE 1 is allowed to receive data of a DL radio bearer(s), which is aradio bearer to be used for at least downlink transmission, may be thesame as or different from the cell(s) on which the data transmissionabout the UL radio bearer(s) is allowed.

FIG. 10 shows an example of information elements (IEs) used by theintegrated eNB 2, the LTE+eNB 5, or the 5G specific eNB 6 to indicate tothe 5G UE 1 the specific cell to be used for UL transmission.Specifically, FIG. 10 shows a modification of the SCellToAddModList IEcontained in the RRC Connection Reconfiguration message. TheSCellToAddModList IE includes a list of the secondary cells (SCell(s))to be added (or modified) to the 5G UE 1. The “available-drbList” (1001)shown in FIG. 10 indicates a list of DRBs which the 5G UE is allowed totransmit on the secondary cell, with regard to each of the secondarycells to be added or modified. The “available-drbList” (1001) includesone or more DRB identifiers (e.g., DRB-Identity (1004)), as shown in the“available-drbList” IE (1002). Further, the “available-drbList” IE(1001) may include an information element (e.g., drb-direction (1005))indicating the target bearer direction (i.e., only uplink, onlydownlink, or both uplink and downlink). The information elementindicating the bearer direction may be configured only when the RLC AMmode is applied to the bearer. Further, the “available-drbList” IE(1001) may include an Evolved Packet System (EPS) bearer identifier(e.g., eps-BearerIdentity (1003)).

The 5GCellToAddModList IE may be defined separately from theCellToAddModList IE. The 5GCellToAddModList IE indicates a list of 5GCell(s) to be added (or modified) to the 5G UE 1. In this case, the“available-drbList” (1001) may be included in the 5GCellToAddModList IE,in place of the SCellToAddModList IE. The 5GCellToAddModList IE may betransmitted on an RRC message (e.g., an RRC Connection Reconfigurationmessage or an RRC Connection Setup message) together with theSCellToAddModList IE, or in place of the SCellToAddModList IE.

As in the above-described examples described with reference to FIGS. 9and 10, to use the RRC configuration to configure the UE 1 with therelationship (or mapping) between each UL radio bearer and a cell(s) onwhich data of the UL radio bearer is to be transmitted provides thefollowing advantages, for example. Even when UL radio bearers are mappedto different combinations of specific cells, the RRC configuration isable to easily specify the mapping, as shown in the examples in FIGS. 9and 10. For example, when a UL radio bearer #A is mapped to cells #a and#b and, meanwhile, a UL radio bearer #B is mapped to cells #b and #c,the RRC configuration can specify these mappings in accordance with theexamples shown in FIGS. 9 and 10.

Next, a specific example of operations of the 5G UE 1 will be described.In response to the indication from the integrated eNB 2, the LTE+eNB 5,or the 5G specific eNB 6, the 5G UE 1 restricts a cell(s) to be used totransmit each UL radio bearer. Specifically, the integrated RRC layer401 of the 5G UE 1 controls the integrated PDCP layer 602 (402), the LTEMAC layer 604 (404), and the New MAC layer 607 (407) so as to specify acell(s) to be used to transmit each UL radio bearer, in accordance withthe indication from the integrated eNB 2, the LTE+eNB 5, or the 5Gspecific eNB 6.

The control on the integrated PDCP layer 602 includes indicating whichone of the LTE RLC layer 603 and the New RLC layer 606 the PDCP entity6023 should send UL PDCP PDUs of the integrated radio bearer (orintegrated bearer) should send to. The PDCP entity 6023 routes the ULPDCP PDUs of the integrated radio bearer to either the RLC entity 6032for LTE or the RLC entity 6062 for New 5G, in accordance with theindication from the integrated RRC layer 601.

The control on each MAC layer includes indicating a specific cell whichthe MAC entity should multiplex RLC PDUs from each RLC entity (that isassociated with one radio bearer) into an uplink transport block of. Forexample, in response to receiving from the integrated RRC layer 401 theindication indicating that data of the DRB #1 is to be transmitted onthe LTE cell 21 (i.e., Cell #1), the MAC entity 6041 for LTE operates tomultiplex the RLC PDUs from the RLC entity 6031 into the UL transportblock to be sent to the physical layer corresponding to the LTE cell 21(i.e., Cell #1), and operates not to multiplex the RLC PDUs from the RLCentity 6031 into the UL transport block to be sent to the physical layercorresponding to the LTE cell 22 (i.e., Cell #2). In a similar way, inresponse to receiving the indication indicating that data of the DRB #3(i.e., integrated bearer) is to be transmitted on the LTE cell 22 (i.e.,Cell #2), the MAC entity 6041 for LTE operates to multiplex the RLC PDUsfrom the RLC entity 6032 to the UL transport block to be sent to thephysical layer corresponding to the LTE cell 22 (i.e., Cell #2).

As will be understood from the above description, in this embodiment,the integrated eNB 2 is configured to transmit, to the 5G UE 1,configuration information indicating, on a cell-by-cell basis, at leastone specific cell that the 5G UE 1 should use to transmit the data ofeach UL radio bearer. In other words, the integrated eNB 2 indicateswhether transmission of the data of each UL radio bearer is valid (orallowed) for each cell that has been configured for the 5G UE 1 and hasbeen activated. Meanwhile, the 5G UE 1 is configured to transmit data(i.e., uplink PDCP PDUs) of each UL radio bearer through the specificcell(s) indicated by the integrated eNB 2 in accordance with theconfiguration information received from the integrated eNB 2.Accordingly, it allows the integrated eNB 2 to indicate, to the 5G UE 1,the specific cell(s) on which the 5G UE 1 should perform the ULtransmission in the 5G radio architecture that provides tightinterworking of the LTE RAT and the New 5G RAT.

The integrated eNB 2 may configure, for example, N LTE cells and M New5G cells in the 5G UE 1 as serving cells. Here, N and M are each aninteger greater than or equal to 2. In this case, the integrated eNB 2may select n LTE cells and m New 5G cells as the specific cells that areallowed to be used to transmit the data of an UL radio bearer. Here, nis a positive integer smaller than N and m is a positive integer smallerthan M.

When the non co-located deployments are used, the LTE+eNB 5 or the 5Gspecific eNB 6 transmits to the 5G UE 1 the configuration informationindicating, on a cell-by-cell basis, at least one specific cell to beused to transmit the data of an UL radio bearer(s). The 5G UE 1transmits data (i.e., uplink PDCP PDUs) of each UL radio bearer throughthe indicated specific cell(s) in accordance with the configurationinformation received from the LTE+eNB 5 or the 5G specific eNB 6.Accordingly, it allows the LTE+eNB 5 or the 5G specific eNB 6 toindicate, to the 5G UE 1, the specific cell(s) on which the 5G UE 1should perform the UL transmission in the 5G radio architecture thatprovides tight interworking of the LTE RAT and the New 5G RAT.

In this embodiment, the descriptions have been mainly given in regard tothe UL radio bearer. However, in some implementations, the integratedeNB 2, the LTE+eNB 5, or the 5G specific eNB 6 may transmit, to the 5GUE 1, configuration information indicating, on a cell-by-cell basis, atleast one specific cell on which the 5G UE 1 is allowed to be used toreceive data of a downlink (DL) radio bearer(s). The 5G UE 1 may receivedata (i.e., DL PDCP PDUs) of each DL radio bearer through the indicatedspecific cell(s) in accordance with the configuration informationreceived from the integrated eNB 2, the LTE+eNB 5, or the 5G specificeNB 6. The cell(s) on which the 5G UE 1 is allowed to receive data ofthe DL radio bearer(s) may be the same as or different from the cell onwhich the data of the UL radio bearer(s) is allowed to be transmitted.

In this embodiment, the 5G UE 1 may transmit a Scheduling Request (SR)and a Buffer Status Report (BSR) as follows. In some implementations,the 5G UE 1 may determine the cell on which an SR and a BSR are to betransmitted, in accordance with the relationship (or mapping) betweeneach radio bearer and a cell(s) on which the data of the radio bearer isto be transmitted. That is, in order to request the integrated eNB 2 (orthe LTE+eNB 5 or the 5G specific eNB 6) for radio resource allocation totransmit data of an uplink radio bearer (i.e., a radio bearer used atleast for uplink transmission), the 5G UE 1 may transmit an SR and a BSRin the specific cell that corresponds to the mapping of this uplinkradio bearer. Alternatively, the 5G UE 1 may transmit an SR or a BSR orboth in any cell included in the cell group (CG) to which the specificcell corresponding to the mapping of this uplink radio bearer belongs.Alternatively, the 5G UE 1 may transmit an SR or a BSR or both in anycell with which the 5G UE 1 has been configured with UL (i.e., cellconfigured with UL).

In this embodiment, when at least one or all of the one or more cells inwhich a radio bearer has been mapped (or configured) is/are released,the 5G UE 1 may autonomously disable the corresponding mapping. Further,in a fall back operation, the UE 1 may transmit data of the radio bearerthrough any cell (in response to the reception of the UL grant).Meanwhile, the integrated eNB 2 (or the LTE+eNB 5 or the 5G specific eNB6) may disable the mapping and perform the reception operationcorresponding to the fall back operation in the 5G UE 1. In this case,the integrated eNB 2 (or the LTE+eNB 5 or the 5G specific eNB 6) maysend to at least one core network node (e.g., MME) a message thattriggers the change in the bearer configuration in the core network(e.g., the integrated EPC 41 or the 5G specific EPC 42).

Second Embodiment

The examples of a radio communication network and a radio protocol stackaccording to this embodiment are similar to those shown in FIGS. 1 to 6.In this embodiment, selection of a key K_(eNB) to derive temporary keys(e.g., K_(UPenc), K_(RRCin)) used by each PDCP entity in the PDCP layer602 (402) will be described. These temporary keys are used by each PDCPentity, for example, to cipher and decipher the user plane (UP) trafficand the RRC traffic. These temporary keys are derived from the keyK_(eNB) by the 5G UE 1 and the integrated eNB 2 (or the LTE+eNB 5).

In some implementations, the 5G UE 1 and the integrated eNB 2 (or theLTE+eNB 5) may use the first key K_(eNB) to cipher and decipher data ofa radio bearer(s) of a certain bearer type and use the second keysub-K_(eNB) to cipher and decipher data of a radio bearer(s) of anotherbearer type. The second key sub-K_(eNB) may be derived from the firstkey K_(eNB), similar to the key S-K_(eNB) used for SCG bearers in DualConnectivity (DC). As shown in FIG. 11, for example, the 5G UE 1 and theintegrated eNB 2 (or the LTE+eNB 5) may use the first key K_(eNB) tocipher and decipher data of LTE bearers (e.g., the DRB #1 shown in FIG.6) and integrated bearers (e.g., the DRB #3 shown in FIG. 6) and use thesecond key sub-K_(eNB) to cipher and decipher data of New 5G bearers(e.g., the DRB #2 shown in FIG. 6).

In some implementations, the 5G UE 1 and the integrated eNB 2 (or theLTE+eNB 5) may select the key based on the relationship (or mapping)between each radio bearer and a cell(s) on which the data of the radiobearer is to be transmitted. Specifically, as shown in FIG. 12, the 5GUE 1 and the integrated eNB 2 (or the LTE+eNB 5) may use the first keyK_(eNB) to cipher and decipher data of radio bearers transmitted throughthe LTE CG and use the second key sub-K_(eNB) to cipher and decipherdata of radio bearers transmitted via the New 5G CG. In the exampleshown in FIG. 12, the first key K_(eNB) is used to cipher and decipherdata of an integrated bearer when this data is transmitted on the LTECG, and the second key sub-K_(eNB) is used to cipher and decipher dataof an integrated bearer when this data is transmitted on the New 5G CG.

Third Embodiment

The examples of a radio communication network and a radio protocol stackaccording to this embodiment are similar to those shown in FIGS. 1 to 6.In this embodiment, an operation of transmitting UL PDCP PDUs of anintegrated UL radio bearer (e.g., the DRB #3 in FIG. 6) by the 5G UE 1will be described.

FIG. 13 is a flowchart showing one example (Process 1300) of operationsof the 5G UE 1 (i.e., the integrated PDCP layer 602) according to thisembodiment. In Step 1301, the 5G UE 1 (the integrated PDCP layer 602)generates UL PDCP PDUs from data of an integrated UL radio bearer. InStep 1302, the 5G UE 1 (the integrated PDCP layer 602) determines whichone of the LTE protocol stack (e.g., the LTE RLC layer 603 and the LTEMAC layer 604) and the New 5G protocol stack (e.g., the New RLC layer606 and the New MAC layer 607) is to be used for transmission of the ULPDCP PDUs, while considering the difference in time-domaincharacteristics between the LTE cell and the New 5G cell. Thetime-domain characteristics include, for example, at least one of a TTIlength, a subframe length, and a latency time from the UL grantreception to the UL transmission.

For example, if at least one of the TTI length, the subframe length, andthe latency time of the New 5G cell is shorter than that of the LTEcell, the 5G UE 1 may preferentially use the New 5G cell. This isparticularly beneficial when the size of the data to be transmitted(e.g., UL PDCP PDU) is small. Alternatively, when at least one of theTTI length and the subframe length of the LTE cell is longer than thatof the New 5G cell, the 5G UE 1 may preferentially use the LTE cell.This may be beneficial when, for example, the size of the data to betransmitted is large.

Further or alternatively, the time-domain characteristics may include adifference in subframe structure or in frame structure between the LTEcell and the New 5G cell. For example, with regard to the subframe ofthe New 5G cell, at least two of an uplink (or downlink) physicalcontrol channel (e.g., PUCCH or PDCCH), a downlink (or uplink) physicalcontrol channel, and an uplink (or downlink) physical data channel(e.g., PUSCH or PDSCH) may be time-multiplexed into one subframe (e.g.,in this order). In this case, it is expected that the aforementionedlatency time from the UL grant reception to the UL transmission willbecome shorter.

Further, different New 5G cells may have different characteristics. Forexample, the 5G UE 1 can use a plurality of New 5G cells havingdifferent characteristics when the 5G UE 1 has been configured with CAor DC and the plurality of cells has been activated. In this case, the5G UE 1 may determine a cell(s) on which data (e.g., UL PDCP PDUs) is tobe transmitted in consideration of the characteristics in time domain ofthese New 5G cells. The difference in the characteristics among theseNew 5G cells may be, for example, a difference in TTI length due to adifference in subframe structure or in Numerology (e.g., subcarrierspacing, sampling rate). Alternatively, it may be regarding whether amethod for reducing a latency until the uplink data transmission (e.g.,Semi-Persistent Scheduling, Contention-based PUSCH transmission) isapplied to the respective New 5G cells (i.e., whether the method isconfigured in the 5G UE 1).

In a first example, the amount (total) of pending UL data is taken intoaccount. When the amount (total) of the pending UL data (i.e., UL PDCPPDUs or SDUs) is smaller than a first threshold indicated by theintegrated eNB 2 (or the LTE+eNB 5), the 5G UE 1 may transmit UL data onthe New 5G cell. That is, the integrated PDCP layer 602 (or the PDCPentity 6023) of the 5G UE 1 sends UL PDCP PDUs to the New MAC layer 607(or the MAC entity 6071) via the New RLC layer 606 (or the RLC entity6062).

Further or alternatively, when the amount (total) of the pending UL data(i.e., UL PDCP PDUs or SDUs) exceeds a second threshold indicated by theintegrated eNB 2 (or the LTE+eNB 5), the 5G UE 1 may transmit UL data onthe LTE cell. That is, the integrated PDCP layer 602 (or the PDCP entity6023) of the 5G UE 1 sends UL PDCP PDUs to the LTE MAC layer 604 (or theMAC entity 6041) via the LTE RLC layer 603 (or the RLC entity 6032).

The first threshold may be the same as the second threshold.Alternatively, the first threshold may be smaller than the secondthreshold. In this case, when the amount (total) of the pending UL datais larger than the first threshold but smaller than the secondthreshold, the 5G UE 1 may transmit UL data as appropriate on a cell(s)on which the UL grant has been received.

In a second example, the packet size (per packet) of the pending UL datais taken into account. The packet size may be, for example, any one ofthe PDCP-SDU size, the PDCP-PDU size, and the IP-packet size. Thepending UL data may include UL data to which a PDCP SN has beenallocated and that is stored in the UL PDCP buffer, and it may furtherinclude UL data to which a PDCP SN has not yet been allocated. When thepacket size of the pending UL data (e.g., UL PDCP SDUs) is smaller thana third threshold indicated by the integrated eNB 2 (or the LTE+eNB 5),the 5G UE 1 may transmit this UL data on the New 5G cell. That is, theintegrated PDCP layer 602 (or the PDCP entity 6023) of the 5G UE 1 sendsUL PDCP PDUs to the New MAC layer 607 (or the MAC entity 6071) via theNew RLC layer 606 (or the RLC entity 6062).

Further or alternatively, when the packet size of the pending UL data(e.g., UL PDCP SDUs) exceeds a fourth threshold indicated by theintegrated eNB 2 (or the LTE+eNB 5), the 5G UE 1 may transmit this ULdata on the LTE cell. That is, the integrated PDCP layer 602 (or thePDCP entity 6023) of the 5G UE 1 sends UL PDCP PDUs to the LTE MAC layer604 (or the MAC entity 6041) via the LTE RLC layer 603 (or the RLCentity 6032).

The third threshold may be the same as the fourth threshold.Alternatively, the third threshold may be smaller than the fourththreshold. In this case, when the packet size of the pending UL data islarger than the third threshold but smaller than the fourth threshold,the 5G UE 1 may transmit this UL data as appropriate on a cell(s) onwhich the UL grant has been received.

In a third example, the difference in TTI between the 5G RAT and the LTERAT is taken into account. As one example, it is assumed a case in whichthe TTI of the 5G RAT (e.g., 0.2 ms TTI) is shorter than the TTI of theLTE RAT (i.e., 1 ms). In this case, the 5G UE 1 may preferentially usethe New 5G RAT over the LTE RAT to transmit PDCP PDUs regarding anintegrated UL radio bearer. In some implementations, in response toreceiving UL grants in both the LTE cell and the New 5G cellsubstantially at the same timing, the integrated PDCP layer 602 (or thePDCP entity 6023) of the 5G UE 1 first sends UL PDCP PDUs to the New MAClayer 607 (or the MAC entity 6071) via the New RLC layer 606 (the RLCentity 6062) in accordance with the UL grant in the New 5G cell. Ifthere are pending UL PDCP PDUs, the integrated PDCP layer 602 (or thePDCP entity 6023) of the 5G UE 1 further sends UL PDCP PDUs to the LTEMAC layer 604 (or the MAC entity 6041) via the LTE RLC layer 603 (or theRLC entity 6032) in accordance with the UL grant in the LTE cell.

Alternatively, the 5G UE 1 may preferentially use the LTE RAT over theNew 5G RAT to transmit PDCP PDUs regarding an integrated UL radiobearer. Further, in order to transmit a Dedicated Scheduling Request(D-SR) and an SRB, the 5G UE 1 may perform a process similar to theabove-described transmission of UL PDCP PDUs.

The reception of UL grants in both the LTE cell and the New 5G cellsubstantially at the same timing may be reception of UL grants in thesame subframe (or the same TTI). Alternatively, the reception of ULgrants substantially at the same timing may be determined depending onwhether the PDCP layer 602 receives notifications regarding thereception of an UL grant from both the lower layer of the LTE and thelower layer of the New 5G in the same subframe (or the same TTI).Alternatively, the reception of UL grants substantially at the sametiming may be determined depending on whether the PDCP layer 602 cantransmit UL data of the same subframe (or at the same time).

In the following, configuration examples of the 5G UE 1, the integratedeNB 2, the LTE+eNB 5, and the 5G specific eNB 6 according to the aboveembodiments will be described. FIG. 14 is a block diagram showing aconfiguration example of the 5G UE 1. An LTE transceiver 1401 performsanalog RF signal processing regarding the PHY layer of the LTE RAT tocommunicate with the integrated eNB 2 (or the LTE+eNB 5). The analog RFsignal processing performed by the LTE transceiver 1401 includesfrequency up-conversion, frequency down-conversion, and amplification.The LTE transceiver 1401 is coupled to an antenna 1402 and a basebandprocessor 1405. That is, the LTE transceiver 1401 receives modulatedsymbol data (or OFDM symbol data) from the baseband processor 1405,generates a transmission RF signal, and supplies the transmission RFsignal to the antenna 1402. Further, the LTE transceiver 1401 generatesa baseband reception signal based on a reception RF signal received bythe antenna 1402, and supplies the baseband reception signal to thebaseband processor 1405.

A New 5G transceiver 1403 performs analog RF signal processing regardingthe PHY layer of the New 5G RAT to communicate with the integrated eNB 2(or the 5G specific eNB 6). The New 5G transceiver 1403 is coupled to anantenna 1404 and the baseband processor 1405.

The baseband processor 1405 performs digital baseband signal processing(i.e., data-plane processing) and control-plane processing for radiocommunication. The digital baseband signal processing includes (a) datacompression/decompression, (b) data segmentation/concatenation, (c)composition/decomposition of a transmission format (i.e., transmissionframe), (d) channel coding/decoding, (e) modulation (i.e., symbolmapping)/demodulation, and (f) generation of OFDM symbol data (i.e.,baseband OFDM signal) by Inverse Fast Fourier Transform (IFFT).Meanwhile, the control-plane processing includes communicationmanagement of layer 1 (e.g., transmission power control), layer 2 (e.g.,radio resource management and hybrid automatic repeat request (HARQ)processing), and layer 3 (e.g., signalling regarding attach, mobility,and packet communication).

In the case of LTE and LTE-Advanced, for example, the digital basebandsignal processing performed by the baseband processor 1405 may includesignal processing of a Packet Data Convergence Protocol (PDCP) layer, aRadio Link Control (RLC) layer, a MAC layer, and a PHY layer. Further,the control plane-processing performed by the baseband processor 1405may include processing of a Non-Access Stratum (NAS) protocol, an RRCprotocol, and MAC CEs.

The baseband processor 1405 may include a modem processor (e.g., aDigital Signal Processor (DSP)) that performs the digital basebandsignal processing and a protocol stack processor (e.g., a CentralProcessing Unit (CPU) or a Micro Processing Unit (MPU)) that performsthe control-plane processing. In this case, the protocol stackprocessor, which performs the control-plane processing, may beintegrated with an application processor 1406 described in thefollowing.

The application processor 1406 is also referred to as a CPU, an MPU, amicroprocessor, or a processor core. The application processor 1406 mayinclude a plurality of processors (processor cores). The applicationprocessor 1406 loads a system software program (Operating System (OS))and various application programs (e.g., communication application thatacquires metering data or sensing data) from a memory 1408 or fromanother memory (not shown) and executes these programs, therebyproviding various functions of the 5G UE 1.

In some implementations, as represented by a dashed line (1407) in FIG.14, the baseband processor 1405 and the application processor 1406 maybe integrated on a single chip. In other words, the baseband processor1405 and the application processor 1406 may be implemented in a singleSystem on Chip (SoC) device 1407. An SoC device may be referred to as asystem Large Scale Integration (LSI) or a chipset.

The memory 1408 is a volatile memory, a non-volatile memory, or acombination thereof. The memory 1408 may include a plurality of memorydevices that are physically independent from each other. The volatilememory is, for example, a Static Random Access Memory (SRAM), a DynamicRAM (DRAM), or a combination thereof. The non-volatile memory is, forexample, a mask Read Only Memory (MROM), an Electrically ErasableProgrammable ROM (EEPROM), a flash memory, a hard disc drive, or anycombination thereof. The memory 1408 may include, for example, anexternal memory device that can be accessed from the baseband processor1405, the application processor 1406, and the SoC 1407. The memory 1408may include an internal memory device that is integrated in the basebandprocessor 1405, the application processor 1406, or the SoC 1407.Further, the memory 1408 may include a memory in a Universal IntegratedCircuit Card (UICC).

The memory 1408 may store one or more software modules (computerprograms) 1409 including instructions and data to perform the processingby the 5G UE 1 described in the above embodiments. In someimplementations, the baseband processor 1405 or the applicationprocessor 1406 may load these software modules 1409 from the memory 1408and execute the loaded software modules, thereby performing theprocessing of the 5G UE 1 described in the above embodiments.

FIG. 15 is a block diagram showing a configuration example of theintegrated eNB 2 according to the above embodiments. Referring to FIG.15, the eNB 2 includes an LTE transceiver 1501, a New 5G transceiver1503, a network interface 1505, a processor 1506, and a memory 1507. TheLTE transceiver 1501 performs analog RF signal processing regarding thePHY layer of the LTE RAT to communicate with the 5G UE 1 via an LTEcell. The LTE transceiver 1501 may include a plurality of transceivers.The LTE transceiver 1501 is coupled to an antenna 1502 and the processor1506.

The New 5G transceiver 1503 performs analog RF signal processingregarding the PHY layer of the New 5G RAT to communicate with the 5G UE1 via a New 5G cell. The New 5G transceiver 1503 is coupled to anantenna 1504 and the baseband processor 1506.

The network interface 1505 is used to communicate with a network node inthe integrated EPC 41 or the 5G specific EPC 42 (e.g., a MobilityManagement Entity (MME) and a Serving Gateway (S-GW)), and tocommunicate with other eNBs. The network interface 1505 may include, forexample, a network interface card (NIC) conforming to the IEEE 802.3series.

The processor 1506 performs digital baseband signal processing (i.e.,data-plane processing) and control-plane processing for radiocommunication. In the case of LTE and LTE-Advanced, for example, thedigital baseband signal processing performed by the processor 1506 mayinclude signal processing of the PDCP layer, the RLC layer, the MAClayer, and the PHY layer. Further, the control-plane processingperformed by the processor 1506 may include processing of the 51protocol, the RRC protocol, and MAC CEs.

The processor 1506 may include a plurality of processors. The processor1506 may include, for example, a modem processor (e.g., DSP) thatperforms the digital baseband signal processing and a protocol stackprocessor (e.g., a CPU or an MPU) that performs the control-planeprocessing.

The memory 1507 is composed of a combination of a volatile memory and anon-volatile memory. The volatile memory is, for example, an SRAM, aDRAM, or a combination thereof. The non-volatile memory is, for example,an MROM, a PROM, a flash memory, a hard disc drive, or a combinationthereof. The memory 1507 may include a storage located apart from theprocessor 1506. In this case, the processor 1506 may access the memory1507 via the network interface 1505 or an I/O interface (not shown).

The memory 1507 may store a software module(s) (computer program(s))1508 including instructions and data for performing processing by theintegrated eNB 2 described in the above embodiments. In someimplementations, the processor 1506 may be configured to load thesoftware module(s) 1508 from the memory 1507 and execute the loadedsoftware module(s), thereby performing processing of the integrated eNB2 described in the above embodiments.

The configurations of the LTE+eNB 5 and the 5G specific eNB 6 may besimilar to the configuration of the integrated eNB 2 shown in FIG. 15.However, the LTE+eNB 5 does not need to include the New 5G transceiver1503 and the 5G specific eNB 6 does not need to include the LTEtransceiver 1501.

As described above with reference to FIGS. 14 and 15, each of theprocessors included in the 5G UE 1, the integrated eNB 2, the LTE+eNB 5,and the 5G specific eNB 6 according to the above embodiments executesone or more programs including instructions to cause a computer toperform an algorithm described with reference to the drawings. Theprogram(s) can be stored and provided to a computer using any type ofnon-transitory computer readable media. Non-transitory computer readablemedia include any type of tangible storage media. Examples ofnon-transitory computer readable media include magnetic storage media(such as flexible disks, magnetic tapes, hard disk drives, etc.),optical magnetic storage media (e.g., magneto-optical disks), CompactDisc Read Only Memory (CD-ROM), CD-R, CD-R/W, and semiconductor memories(such as mask ROM, Programmable ROM (PROM), Erasable PROM (EPROM), flashROM, Random Access Memory (RAM), etc.). The program(s) may be providedto a computer using any type of transitory computer readable media.Examples of transitory computer readable media include electric signals,optical signals, and electromagnetic waves. Transitory computer readablemedia can provide the program to a computer via a wired communicationline (e.g., electric wires, and optical fibers) or a wirelesscommunication line.

OTHER EMBODIMENTS

Each of the above-described embodiments may be used individually, or twoor more embodiments may be appropriately combined with one another.

The base stations, the integrated eNB 2, the LTE+eNB 5, the 5G specificeNB 6, the BBU (or the DU), and the RRH (or the RU) described in theabove embodiments each may be referred to as a radio station or a radioaccess network (RAN) node. In other words, the processing and theoperations performed by the base stations, the base station system, theintegrated eNB 2, the LTE+eNB 5, the 5G specific eNB 6, the BBU (DU), orthe RRH (RU) described in the above embodiments may be provided by anyone or more radio stations (i.e., RAN nodes).

Some of the above embodiments provide the examples in which the radiostation (e.g., the integrated eNB 2, the LTE+eNB 5, or the 5G specificeNB 6) maps a radio bearer of the UE 1 to one or more specific cells ona cell-by-cell basis. In one example, the radio bearer may be mapped, ona cell-group basis, to a plurality of specific cells on which uplinkcontrol information (UCI) is transmitted (i.e., PUCCH CG), or tospecific cells regarding the uplink transmission timing (i.e., TAG).

Further or alternatively, the radio station (e.g., the integrated eNB 2,the LTE+eNB 5, or the 5G specific eNB 6) may determine, on acell-by-cell basis, a specific cell to which each data-packet flow(e.g., IP flow, Service Data Flow (SDF)) transmitted on one radio beareris mapped. In order to achieve this, the core network (e.g., the P-GW orthe S-GW) may add identification information (e.g., flow identificationinformation) for specifying the data packet flow to user plane data tobe transmitted to the radio station (e.g., the integrated eNB 2, theLTE+eNB 5, or the 5G specific eNB 6). The radio station may map the datapacket flow to a specific cell on a cell-by-cell basis based on the flowidentification information. In other words, the radio station may selecton a cell-by-cell basis, based on the flow identification information, aspecific cell on which data of the data packet flow is to betransmitted. In a similar way, the access stratum (AS) layer of the 5GUE 1 may receive, from the application layer or the NAS layer, userplane data to which the flow identification information has been added,and then map the data packet flow to a specific cell on a cell-by-cellbasis based on the flow identification information. In other words, theAS layer of the UE 1 may select on a cell-by-cell basis, based on theflow identification information, a specific cell on which data of thedata packet flow is to be transmitted. The flow identificationinformation may be newly defined. Alternatively, a Flow PriorityIndicator (FPI) may be used as the flow identification information. TheFPI indicates a priority among a plurality of data packet flows in oneparticular bearer (e.g., an EPS-bearer).

Further, the above-described embodiments are merely examples ofapplications of the technical ideas obtained by the inventors. Needlessto say, these technical ideas are not limited to the above-describedembodiments and various modifications can be made thereto.

For example, the whole or part of the above embodiments can be describedas, but not limited to, the following supplementary notes.

(Supplementary Note 1)

A radio station system comprising:

one or more radio stations configured to:

-   -   provide a first radio protocol stack to communicate with a radio        terminal on one or more first cells in accordance with a first        radio access technology, a second radio protocol stack to        communicate with the radio terminal on one or more second cells        in accordance with a second radio access technology, and a        common Packet Data Convergence Protocol (PDCP) layer associated        with both the first and second radio protocol stacks;    -   select from the one or more first cells and the one or more        second cells, on a cell-by-cell basis, at least one specific        cell on which the radio terminal is allowed to perform at least        one of data transmission and data reception on a radio bearer        used for uplink transmission or downlink transmission or both        via the common PDCP layer; and    -   transmit configuration information indicating the at least one        specific cell to the radio terminal.

(Supplementary Note 2)

The radio station system according to Supplementary Note 1, wherein

the configuration information comprises a bearer configuration regardingthe radio bearer, and

the bearer configuration comprises an indication indicating, on acell-by-cell basis, the at least one specific cell on which the radioterminal is allowed to perform the data transmission on the radiobearer.

(Supplementary Note 3)

The radio station system according to Supplementary Note 1, wherein

the configuration information comprises a cell configuration regardingat least one serving cell, and

the cell configuration indicates whether the radio terminal is allowedto perform the data transmission on the radio bearer in each servingcell.

(Supplementary Note 4)

The radio station system according to any one of Supplementary Notes 1to 3, wherein each of the first and second radio protocol stackscomprises a Radio Link Control (RLC) layer that provides a service forthe common PDCP layer and a Medium Access Control (MAC) layer thatprovides a service for the RLC layer.

(Supplementary Note 5)

The radio station system according to any one of Supplementary Notes 1to 4, wherein the one or more first cells and the one or more secondcells are cells that have been configured for the radio terminal andhave been activated.

(Supplementary Note 6)

The radio station system according to any one of Supplementary Notes 1to 5, wherein the common PDCP layer is configured to:

-   -   provide a first radio bearer that uses the first radio protocol        stack, and provide a second radio bearer that uses the second        radio protocol stack; and    -   derive a temporary key for ciphering or deciphering of data of        the first radio bearer from a first key, and derive a temporary        key for ciphering or deciphering of data of the second radio        bearer from a second key that differs from the first key.

(Supplementary Note 7)

The radio station system according to Supplementary Note 6, wherein thecommon PDCP layer is configured to:

-   -   provide an integrated radio bearer that uses both the first and        second radio protocol stacks; and    -   derive a temporary key for ciphering or deciphering of data of        the integrated radio bearer from the first key.

(Supplementary Note 8)

The radio station system according to Supplementary Note 6, wherein thecommon PDCP layer is configured to:

-   -   provide an integrated bearer that uses both the first and second        radio protocol stacks; and    -   derive, from the first key, a temporary key for ciphering or        deciphering of data of the integrated radio bearer transferred        via the first radio protocol stack, and derive, from the second        key, a temporary key for ciphering or deciphering of data of the        integrated radio bearer transferred via the second radio        protocol stack.

(Supplementary Note 9)

A method in a radio station system comprising one or more radiostations, the method comprising:

providing a first radio protocol stack to communicate with a radioterminal on one or more first cells in accordance with a first radioaccess technology, a second radio protocol stack to communicate with theradio terminal on one or more second cells in accordance with a secondradio access technology, and a common Packet Data Convergence Protocol(PDCP) layer associated with both the first and second radio protocolstacks;

selecting from the one or more first cells and the one or more secondcells, on a cell-by-cell basis, at least one specific cell on which theradio terminal is allowed to perform at least one of data transmissionand data reception on a radio bearer used for uplink transmission ordownlink transmission or both PDCP layer; and

transmitting configuration information indicating the at least onespecific cell to the radio terminal.

(Supplementary Note 10)

A non-transitory computer readable medium storing a program for causinga computer to perform a method in a radio station system comprising oneor more radio stations, the method comprising:

providing a first radio protocol stack to communicate with a radioterminal on one or more first cells in accordance with a first radioaccess technology, a second radio protocol stack to communicate with theradio terminal on one or more second cells in accordance with a secondradio access technology, and a common Packet Data Convergence Protocol(PDCP) layer associated with both the first and second radio protocolstacks;

selecting from the one or more first cells and the one or more secondcells, on a cell-by-cell basis, at least one specific cell on which theradio terminal is allowed to perform at least one of data transmissionand data reception on a radio bearer used for uplink transmission ordownlink transmission or both via the common PDCP layer; and

transmitting configuration information indicating the at least onespecific cell to the radio terminal.

(Supplementary Note 11)

A radio terminal comprising:

a memory; and

at least one processor coupled to the memory and configured to:

-   -   provide a first radio protocol stack to communicate with a radio        station on one or more first cells in accordance with a first        radio access technology, a second radio protocol stack to        communicate with the radio station on one or more second cells        in accordance with a second radio access technology, and a        common Packet Data Convergence Protocol (PDCP) layer associated        with both the first and second radio protocol stacks;    -   receive, from the radio station, configuration information        indicating, on a cell-by-cell basis, at least one specific cell        on which the radio terminal is allowed to perform at least one        of data transmission and data reception on a radio bearer used        for uplink transmission or downlink transmission or both via the        common PDCP layer; and    -   perform at least one of the data transmission and the data        reception on the radio bearer via the at least one specific cell        in accordance with the configuration information.

(Supplementary Note 12)

The radio terminal according to Supplementary Note 11, wherein

the configuration information comprises a bearer configuration regardingthe radio bearer, and

the bearer configuration comprises an indication indicating, on acell-by-cell basis, the at least one specific cell on which the radioterminal is allowed to perform the data transmission on the radiobearer.

(Supplementary Note 13)

The radio terminal according to Supplementary Note 11, wherein

the configuration information comprises a cell configuration regardingat least one serving cell, and

the cell configuration indicates whether the radio terminal is allowedto perform the data transmission on the radio bearer in each servingcell.

(Supplementary Note 14)

The radio terminal according to any one of Supplementary Notes 11 to 13,wherein each of the first and second radio protocol stacks comprises aRadio Link Control (RLC) layer that provides a service for the commonPDCP layer and a Medium Access Control (MAC) layer that provides aservice for the RLC layer.

(Supplementary Note 15)

The radio terminal according to Supplementary Note 14, wherein

the at least one processor is further configured to provide anintegrated Radio Resource Control (RRC) layer, and

the common RRC layer is configured to control the common PDCP layer andrespective MAC layers of the first and second radio protocol stacks, inorder to indicate the at least one specific cell used for the datatransmission on the radio bearer.

(Supplementary Note 16)

The radio terminal according to Supplementary Note 15, wherein

the radio bearer is an integrated radio bearer that uses both the firstand second radio protocol stacks, and

the control on the common PDCP layer by the common RRC layer comprisesindicating which one of the RLC layers of the first and second radioprotocol stacks the common PDCP layer should send the uplink PDCPprotocol data units (PDUs) to.

(Supplementary Note 17)

The radio terminal according to Supplementary Note 15 or 16, wherein thecontrol on each MAC layer by the common RRC layer comprises indicating aspecific cell which the MAC entity should multiplex RLC PDUs into anuplink transport block of.

(Supplementary Note 18)

The radio terminal according to any one of Supplementary Notes 11 to 17,wherein each of the one or more first cells and the one or more secondcells is a cell that have been configured for the radio terminal andhave been activated.

(Supplementary Note 19)

The radio terminal according to any one of Supplementary Notes 11 to 18,wherein the common PDCP layer is configured to:

-   -   provide a first radio bearer that uses the first radio protocol        stack, and provide a second radio bearer that uses the second        radio protocol stack; and    -   derive a temporary key for ciphering or deciphering of data of        the first radio bearer from a first key, and derive a temporary        key for ciphering or deciphering of data of the second radio        bearer from a second key that differs from the first key.

(Supplementary Note 20)

The radio terminal according to Supplementary Note 19, wherein thecommon PDCP layer is configured to:

-   -   provide an integrated radio bearer that uses both the first and        second radio protocol stacks; and    -   derive a temporary key for ciphering or deciphering of data of        the integrated radio bearer from the first key.

(Supplementary Note 21)

The radio terminal according to Supplementary Note 19, wherein thecommon PDCP layer is configured to:

-   -   provide an integrated bearer that uses both the first and second        radio protocol stacks; and    -   derive, from the first key, a temporary key for ciphering or        deciphering of data of the integrated radio bearer transferred        via the first radio protocol stack, and derive, from the second        key, a temporary key for ciphering or deciphering of data of the        integrated radio bearer transferred via the second radio        protocol stack.

(Supplementary Note 22)

A method in a radio terminal, the method comprising:

providing a first radio protocol stack to communicate with a radiostation on one or more first cells in accordance with a first radioaccess technology, a second radio protocol stack to communicate with theradio station on one or more second cells in accordance with a secondradio access technology, and a common Packet Data Convergence Protocol(PDCP) layer associated with both the first and second radio protocolstacks;

receiving, from the radio station, configuration information indicating,on a cell-by-cell basis, at least one specific cell on which the radioterminal is allowed to perform at least one of data transmission anddata reception on a radio bearer used for uplink transmission ordownlink transmission or both via the common PDCP layer; and

performing at least one of the data transmission and the data receptionon the radio bearer via the at least one specific cell in accordancewith the configuration information.

(Supplementary Note 23)

A non-transitory computer readable medium storing a program for causinga computer to perform a method in a radio terminal, the methodcomprising:

providing a first radio protocol stack to communicate with a radiostation on one or more first cells in accordance with a first radioaccess technology, a second radio protocol stack to communicate with theradio station on one or more second cells in accordance with a secondradio access technology, and a common Packet Data Convergence Protocol(PDCP) layer associated with both the first and second radio protocolstacks;

receiving, from the radio station, configuration information indicating,on a cell-by-cell basis, at least one specific cell on which the radioterminal is allowed to perform at least one of data transmission anddata reception on a radio bearer used for uplink transmission ordownlink transmission or both via the common PDCP layer; and

performing at least one of the data transmission and the data receptionon the radio bearer via the at least one specific cell in accordancewith the configuration information.

(Supplementary Note 24)

A radio terminal comprising:

a memory; and

at least one processor coupled to the memory, wherein

the at least one processor is configured to provide a first radioprotocol stack to communicate with a radio terminal on one or more firstcells in accordance with a first radio access technology, a second radioprotocol stack to communicate with the radio terminal on one or moresecond cells in accordance with a second radio access technology, and acommon Packet Data Convergence Protocol (PDCP) layer associated withboth the first and second radio protocol stacks,

the common PDCP layer is configured to provide an integrated radiobearer that uses both the first and second radio protocol stacks for anupper layer, and

the at least one processor is configured to determine which one of thefirst and second radio protocol stacks is to be used for transmission ofuplink PDCP protocol data units (PDUs) regarding the integrated radiobearer, while taking into account a difference in time-domaincharacteristics between the one or more first cells and the one or moresecond cells.

(Supplementary Note 25)

A method in a radio terminal, the method comprising:

providing a first radio protocol stack to communicate with a radioterminal on one or more first cells in accordance with a first radioaccess technology, a second radio protocol stack to communicate with theradio terminal on one or more second cells in accordance with a secondradio access technology, and a common Packet Data Convergence Protocol(PDCP) layer associated with both the first and second radio protocolstacks, the common PDCP layer providing an integrated radio bearer thatuses both the first and second radio protocol stacks for an upper layer;and

determining which one of the first and second radio protocol stacks tobe used for transmission of uplink PDCP protocol data units (PDUs)regarding the integrated radio bearer, while taking into account adifference in time-domain characteristics between the one or more firstcells and the one or more second cells.

(Supplementary Note 26)

A non-transitory computer readable medium storing a program for causinga computer to perform a method in a radio terminal, the methodcomprising:

providing a first radio protocol stack to communicate with a radioterminal on one or more first cells in accordance with a first radioaccess technology, a second radio protocol stack to communicate with theradio terminal on one or more second cells in accordance with a secondradio access technology, and a common Packet Data Convergence Protocol(PDCP) layer associated with both the first and second radio protocolstacks, the common PDCP layer providing an integrated radio bearer thatuses both the first and second radio protocol stacks for an upper layer;and

determining which one of the first and second radio protocol stacks tobe used for transmission of uplink PDCP protocol data units (PDUs)regarding the integrated radio bearer, while taking into account adifference in time-domain characteristics between the one or more firstcells and the one or more second cells.

REFERENCE SIGNS LIST

-   1 RADIO TERMINAL (5G UE)-   2 BASE STATION (INTEGRATED eNB)-   1401 LTE TRANSCEIVER-   1403 NEW 5G TRANSCEIVER-   1405 BASEBAND PROCESSOR-   1406 APPLICATION PROCESSOR-   1408 MEMORY-   1501 LTE TRANSCEIVER-   1503 NEW 5G TRANSCEIVER-   1506 PROCESSOR-   1507 MEMORY

1. A radio station comprising: a memory having stored therein programinstructions; and at least one processor that when executing the programinstructions is configured to: communicate with a radio terminal thatperforms dual connectivity that uses one or more first cells associatedwith a first radio access technology and one or more second cellsassociated with a second radio access technology; provide a first radioprotocol stack to communicate with the radio terminal on the one or morefirst cells in accordance with the first radio access technology;provide a common Packet Data Convergence Protocol (PDCP) layerassociated with both the first radio protocol stack and the second radioprotocol stack during the dual connectivity, the second radio protocolstack being provided in a second radio station for communicating withthe radio terminal on the one or more second cells in accordance withthe second radio access technology; select, from the one or more firstcells and the one or more second cells, on a cell-by-cell basis, atleast one specific cell on which the radio terminal is allowed toperform uplink data transmission on a radio bearer via the common PDCPlayer; and transmit a bearer configuration comprising information thatindicates, on the cell-by-cell basis, the at least one specific cell onwhich the radio terminal is allowed to perform the uplink datatransmission on the radio bearer.
 2. The radio station according toclaim 1, wherein the bearer configuration further comprises a cellconfiguration of at least one serving cell, and the cell configurationindicates whether the radio terminal is allowed to perform the uplinkdata transmission on the radio bearer in each serving cell.
 3. The radiostation according to claim 1, wherein each of the first radio protocolstack and the second radio protocol stack comprises a Radio Link Control(RLC) layer that provides a service for the common PDCP layer and aMedium Access Control (MAC) layer that provides a service for the RLClayer.
 4. The radio station according to claim 1, wherein the one ormore first cells and the one or more second cells are cells that havebeen configured for the radio terminal and have been activated.
 5. Theradio station according to claim 1, wherein the at least one processoris further configured to control the common PDCP layer to: provide afirst radio bearer that uses the first radio protocol stack, and providea second radio bearer that uses the second radio protocol stack; andderive a first temporary key for ciphering or deciphering data of thefirst radio bearer from a first key, and derive a second temporary keyfor ciphering or deciphering data of the second radio bearer from asecond key that differs from the first key.
 6. The radio stationaccording to claim 5, wherein the at least one processor is furtherconfigured to control the common PDCP layer to: provide an integratedradio bearer that uses both the first radio protocol stack and thesecond radio protocol stack; and derive a third temporary key forciphering or deciphering of data of the integrated radio bearer from thefirst key.
 7. The radio station according to claim 5, wherein the atleast one processor is further configured to control the common PDCPlayer to: provide an integrated bearer that uses both the first radioprotocol stack and the second radio protocol stack; and derive, from thefirst key, a third temporary key for ciphering or deciphering of data ofthe integrated radio bearer transferred via the first radio protocolstack, and derive, from the second key, a fourth temporary key forciphering or deciphering of data of the integrated radio bearertransferred via the second radio protocol stack.
 8. The radio stationaccording to claim 1, wherein the radio station is a Master eNB (MeNB)or a Secondary eNB (SeNB).
 9. A method in a radio station, the methodcomprising: communicating with a radio terminal that performs dualconnectivity that uses one or more first cells associated with a firstradio access technology and one or more second cells associated with asecond radio access technology; providing a first radio protocol stackto communicate with the radio terminal on the one or more first cells inaccordance with the first radio access technology; providing a commonPacket Data Convergence Protocol (PDCP) layer associated with both thefirst radio protocol stack and the second radio protocol stack duringthe dual connectivity, the second radio protocol stack being provided ina second radio station for communicating with the radio terminal on theone or more second cells in accordance with the second radio accesstechnology; selecting, from the one or more first cells and the one ormore second cells, on a cell-by-cell basis, at least one specific cellon which the radio terminal is allowed to perform uplink datatransmission on a radio bearer via the common PDCP layer; andtransmitting, to the radio terminal, a bearer configuration comprisinginformation that indicates, on the cell-by-cell basis, the at least onespecific cell on which the radio terminal is allowed to perform theuplink data transmission on the radio bearer.
 10. The method accordingto claim 9, wherein the radio station is a Master eNB (MeNB) or aSecondary eNB (SeNB).
 11. A radio terminal comprising: a memory; and atleast one processor configured to access the memory and configured to:provide a first radio protocol stack to communicate with a first radiostation on one or more first cells in accordance with a first radioaccess technology; provide a second radio protocol stack to communicatewith a second radio station on one or more second cells in accordancewith a second radio access technology; perform dual connectivity thatuses the one or more first cells and the one or more second cells;provide a common Packet Data Convergence Protocol (PDCP) layerassociated with both the first and second radio protocol stacks duringthe dual connectivity; receive, from the first radio station, a bearerconfiguration comprising information that indicates, on a cell-by-cellbasis, at least one specific cell on which the radio terminal is allowedto perform uplink data transmission on a radio bearer via the commonPDCP layer; and perform the uplink data transmission on the radio bearervia the at least one specific cell in accordance with the bearerconfiguration information.
 12. The radio terminal according to claim 11,wherein the bearer configuration further comprises a cell configurationof at least one serving cell, and wherein the cell configurationindicates whether the radio terminal is allowed to perform the uplinkdata transmission on the radio bearer in each serving cell.
 13. Theradio terminal according to claim 11, wherein each of the first radioprotocol stack and the second radio protocol stack comprises a RadioLink Control (RLC) layer that provides a service for the common PDCPlayer and a Medium Access Control (MAC) layer that provides a servicefor the RLC layer.
 14. The radio terminal according to claim 13, whereinthe at least one processor is further configured to provide anintegrated Radio Resource Control (RRC) layer, and wherein theintegrated RRC layer is configured to control the common PDCP layer andrespective MAC layers of the first radio protocol stack and the secondradio protocol stack, in order to indicate the at least one specificcell used for the data transmission on the radio bearer.
 15. The radioterminal according to claim 14, wherein the radio bearer is anintegrated radio bearer that uses both the first radio protocol stackand the second radio protocol stack, and wherein the integrated RRClayer is further configured to determine which one of the RLC layers ofthe first radio protocol stack and the second radio protocol stack thecommon PDCP layer is to send uplink PDCP protocol data units (PDUs) to.16. The radio terminal according to claim 14, wherein the integrated RRClayer is further configured to determine a specific cell to which theMAC entity is to multiplex RLC PDUs into an uplink transport block. 17.The radio terminal according to claim 11, wherein each of the one ormore first cells and the one or more second cells is a cell that havebeen configured for the radio terminal and have been activated.
 18. Theradio terminal according to claim 11, wherein the common PDCP layer isconfigured to: provide a first radio bearer that uses the first radioprotocol stack, and provide a second radio bearer that uses the secondradio protocol stack; and derive a first temporary key for ciphering ordeciphering data of the first radio bearer from a first key, and derivea second temporary key for ciphering or deciphering data of the secondradio bearer from a second key that differs from the first key.
 19. Theradio terminal according to claim 18, wherein the common PDCP layer isconfigured to: provide an integrated radio bearer that uses both thefirst radio protocol stack and the second radio protocol stack; andderive a third temporary key for ciphering or deciphering of data of theintegrated radio bearer from the first key.
 20. The radio terminalaccording to claim 18, wherein the common PDCP layer is configured to:provide an integrated bearer that uses both the first radio protocolstack and the second radio protocol stack; and derive, from the firstkey, a third temporary key for ciphering or deciphering of data of theintegrated radio bearer transferred via the first radio protocol stack,and derive, from the second key, a fourth temporary key for ciphering ordeciphering of data of the integrated radio bearer transferred via thesecond radio protocol stack.
 21. The radio terminal according to claim11, wherein the first radio station is a Master eNB (MeNB) or aSecondary eNB (SeNB).
 22. A method in a radio terminal, the methodcomprising: providing a first radio protocol stack to communicate with afirst radio station on one or more first cells in accordance with afirst radio access technology; providing a second radio protocol stackto communicate with a second radio station on one or more second cellsin accordance with a second radio access technology; performing dualconnectivity that uses the one or more first cells and the one or moresecond cells; providing a common Packet Data Convergence Protocol (PDCP)layer associated with both the first and second radio protocol stacksduring the dual connectivity; receiving, from the first radio station, abearer configuration comprising information that indicates, on acell-by-cell basis, at least one specific cell on which the radioterminal is allowed to perform uplink data transmission on a radiobearer via the common PDCP layer; and performing the uplink datatransmission on the radio bearer via the at least one specific cell inaccordance with the bearer configuration information.
 23. The methodaccording to claim 22, wherein the first radio station is a Master eNB(MeNB) or a Secondary eNB (SeNB).